KR101176370B1 - Delayed Time Compensating Apparatus for LTE Mobile Telecommunications System Using CDMA Mobile TeleCommunications Network - Google Patents

Abstract

The present invention relates to a time delay compensation device of an LTE mobile communication system using a CDMA mobile communication network, and a time delay compensation device of an LTE mobile communication system using a CDMA mobile communication network according to the present invention, using an optical fiber as a transmission medium. LTE mobile communication using a CDMA mobile communication network which compensates the time delay of a transmission signal generated between the donor optical repeater and the remote optical repeater of the LTE mobile communication system using a CDMA mobile communication network including a donor optical repeater and a remote optical repeater. A time delay compensation device of a communication system, comprising: generating a pulse signal and combining the pulse signal with a transmission signal input from the donor optical repeater as an optical signal to a remote optical repeater and corresponding to the pulse signal from the remote optical repeater The pulse response signal reflected and received as an optical signal A delay time measuring unit for measuring a delay time according to the transmission distance; And a delay time compensator for controlling a time delay of a transmission signal transmitted to the base station and the donor optical repeater in response to the delay time according to the transmission distance measured by the delay time measurement unit.
Therefore, the present invention has an effect of providing a time delay compensation device of an LTE mobile communication system that can reduce the system construction cost by using an optical repeater system of a CDMA mobile communication network.
In addition, the present invention has a delay time measuring unit for measuring the delay time according to the transmission distance of the donor optical repeater and the remote optical repeater using the optical signal reflected in the optical cable LTE mobile communication using a CDMA mobile communication network with improved reliability It is effective to provide a time delay compensation device of the system.
In addition, the present invention provides a LTE mobile communication using a CDMA mobile communication network in which a time delay compensation device having a programmable semiconductor having hardware implemented with a program logic for measuring a delay time according to a transmission distance, obtaining a transmission time, and controlling a time delay. It can be easily installed in the free space in the base station of the communication system to effectively implement the system installation.

Description

Delayed Time Compensating Apparatus for LTE Mobile Telecommunications System Using CDMA Mobile TeleCommunications Network}

The present invention relates to a time delay compensation device of an LTE mobile communication system using a CDMA mobile communication network. More particularly, the optical transmission system of a CDMA mobile communication network not only reduces system construction cost but also improves reliability and installs a system. The present invention relates to a time delay compensation device of an LTE mobile communication system using a CDMA mobile communication network.

1 is a diagram illustrating an LTE mobile communication system using an optical path of a CDMA mobile communication network as a transmission medium.

As shown in the figure, a Long Term Evolution (LTE) mobile communication system using a Code Division Multiple Access (CDMA) mobile communication network including a donor optical repeater and a remote optical repeater to use an optical path as a transmission medium is used as the donor optical. Due to the optical path section between the repeater and the remote optical repeater, a system time delay occurs in the optical repeater itself.

As a result, a difference in delay time of a transmission signal between a base station cell and a remote optical repeater cell may occur, thereby limiting interference of the transmission signal and coverage of the transmission signal.

In order to solve this problem, as a conventional technique, a delay time measuring device for measuring a delay time of a transmission signal of an optical path section using a sine wave signal generated by a modem, and an optical cable and an optical switch having different lengths, There has been a description of a time delay adjusting device for adjusting the time delay.

However, the delay time measurement device using the sinusoidal signal generated by the modem is not only inaccurate but also useful when constructing a new optical repeater system. As the program needs to be newly installed, the system installation cost and preparation period increase, which causes a problem of inefficiency. In addition, the time delay control device using the optical cables and optical switches having different lengths requires expensive equipment and deviations are increased. When a large time delay is required, the physical length of the optical cable is increased, thereby increasing the construction cost and making it difficult to install the system.

Therefore, there is an urgent need for a realistic and highly available technology that can provide a time delay compensation device applicable to an LTE mobile communication system that can not only reduce system construction cost but also improve reliability and effectively implement system installation.

Accordingly, an object of the present invention is to provide a time delay compensation device of an LTE mobile communication system which can reduce system construction cost by using an optical repeater system of a CDMA mobile communication network. have.

In addition, the present invention has a delay time measuring unit for measuring the delay time according to the transmission distance of the donor optical repeater and the remote optical repeater using the optical signal reflected in the optical cable LTE mobile communication using a CDMA mobile communication network with improved reliability It is an object of the present invention to provide a device for compensating for the time delay of a system.

In addition, the present invention provides a LTE mobile communication using a CDMA mobile communication network in which a time delay compensation device having a programmable semiconductor having hardware implemented with a program logic for measuring a delay time according to a transmission distance, obtaining a transmission time, and controlling a time delay. It is aimed to effectively implement the system installation by simply installed in the free space in the base station of the communication system.

In order to achieve the above object, a time delay compensation device of an LTE mobile communication system using a CDMA mobile communication network according to an embodiment of the present invention includes a CDMA including a donor optical repeater and a remote optical repeater to use an optical fiber as a transmission medium. A time delay compensation device of an LTE mobile communication system using a CDMA mobile communication network that compensates for a time delay of a transmission signal generated between the donor optical repeater and a remote optical repeater of an LTE mobile communication system using a mobile communication network. And transmit the pulse signal to a remote optical repeater by combining the pulse signal with a transmission signal input from the donor optical repeater and receiving a pulse response signal reflected from the remote optical repeater corresponding to the pulse signal as an optical signal. Delay time measurement for measuring the delay time according to the transmission distance of the transmission signal part; And a delay time compensator for controlling a time delay of a transmission signal transmitted to the base station and the donor optical repeater in response to the delay time according to the transmission distance measured by the delay time measuring unit.

As described above, the present invention has the effect of providing a time delay compensation device of the LTE mobile communication system that can reduce the system construction cost by using the optical repeater system of the CDMA mobile communication network.

In addition, the present invention has a delay time measuring unit for measuring the delay time according to the transmission distance of the donor optical repeater and the remote optical repeater using the optical signal reflected in the optical cable LTE mobile communication using a CDMA mobile communication network with improved reliability It is effective to provide a time delay compensation device of the system.

In addition, the present invention provides a LTE mobile communication using a CDMA mobile communication network in which a time delay compensation device having a programmable semiconductor having hardware implemented with a program logic for measuring a delay time according to a transmission distance, obtaining a transmission time, and controlling a time delay. Easily installed in the free space in the base station of the communication system can effectively implement the system installation.

1 is a diagram illustrating an LTE mobile communication system using an optical path of a CDMA mobile communication network as a transmission medium.
2 is a block diagram showing the overall configuration of the time delay compensation apparatus of the LTE mobile communication system using a CDMA mobile communication network according to an embodiment of the present invention
3 is a detailed configuration diagram illustrating a delay time measuring unit of a time delay compensation device according to an embodiment of the present invention;
4 is a detailed configuration diagram illustrating a delay time compensator of a time delay compensator according to an exemplary embodiment of the present invention.

An apparatus for compensating for time delay of an LTE mobile communication system using a CDMA mobile communication network according to the present invention uses a CDMA mobile communication network including a donor optical repeater 2 and a remote optical repeater 3 to use an optical fiber as a transmission medium. The device compensates the time delay of the transmission signal generated between the donor optical repeater (2) and the remote optical repeater (3).

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing the overall configuration of the time delay compensation apparatus of the LTE mobile communication system using a CDMA mobile communication network according to an embodiment of the present invention.

As shown in FIG. 2, the time delay compensation device 10 of the LTE mobile communication system using the CDMA mobile communication network according to an embodiment of the present invention is provided between a donor optical repeater 2 and a remote optical repeater 3. Including a delay time measuring unit 100 for measuring the delay time according to the transmission distance of the generated transmission signal and a delay time compensation unit 200 for controlling the time delay of the transmission signal corresponding to the delay time according to the transmission distance Is done.

In more detail, the delay time measuring unit 100 generates a pulse signal, converts it into an optical signal, and transmits the measured signal to the remote optical repeater 3, and the reflection from the remote optical repeater 3. And a pulse signal converted into an optical signal by the measurement signal transmitter 120 for receiving a pulse response signal received as an optical signal as an analog signal and converting the signal into a digital signal. The transmission signal and the measurement signal which are combined with the transmission signal input as an optical signal from 2) and transmitted to the remote optical repeater 3 or the optical signal received from the remote optical repeater 3 to the donor optical repeater 2. The optical signal coupler 130 is separated into a pulse response signal input to the receiver 120, and a pulse driving signal is sent to the measurement signal transmitter 110 to control the generation of the pulse signal of the measurement signal transmitter 110. Mental using a digital signal that is received from the lake bride 120 and a measurement control signal calculation section 140 for calculating a delay time according to a transmission distance of the transmitted signal.

Here, the measurement signal control calculator 140 transmits a pulse driving signal to the measurement signal transmitter 110 and is a digital signal from the measurement signal receiver 120. The program logic for counting the time until receiving the pulse response signal is preferably formed of a programmable semiconductor (FPGA) implemented in hardware.

In addition, the delay time measuring unit 100 includes a circulator 150 to isolate the pulse signal transmitted from the remote optical repeater 3 and the pulse response signal received from the remote optical repeater (3).

As described above, the delay time measuring unit 100 of the time delay compensator 10 according to an embodiment of the present invention generates a pulse signal and transmits the pulse signal as an optical signal from the donor optical repeater 2. The signal is transmitted to the remote optical repeater 3 in combination with the signal, and a pulse response signal reflected from the remote optical repeater 3 corresponding to the pulse signal is received as an optical signal, and the delay time according to the transmission distance of the transmission signal is measured. do..

On the other hand, the delay time compensation unit 200 is input from the transmission signal transmitter 210 and the donor optical repeater 2 is formed a path for transmitting the transmission signal input from the base station 1 to the donor optical repeater (2) Performs a calculation process corresponding to the delay time according to the transmission distance of the transmission signal measured by the transmission signal receiving unit 220, and the delay time measuring unit 100 is formed a path for transmitting the transmitted signal to the base station 1 To obtain the transmission time of the transmission signal transmitted to the donor optical repeater 2 and the base station 1 and control the transmission signal transmitter 210 and the transmission signal receiver 220 to control the donor optical repeater 2 and the base station. And a transmission time calculation control unit 230 for controlling the time delay of the transmission signal transmitted to (1).

Here, the transmission time operation control unit 230 generates a program logic for calculating the transmission time of the transmission signal, and generates and sends a control signal for controlling the transmission signal transmitter 210 and the transmission signal receiver 220. The program logic is preferably formed of a programmable semiconductor implemented in hardware.

As described above, the delay time compensator 200 of the time delay compensator 10 according to an embodiment of the present invention corresponds to the delay time according to the transmission distance measured by the delay time measurer 100. ) And the time delay of the transmission signal transmitted to the donor optical repeater (2).

3 is a detailed configuration diagram illustrating a delay time measuring unit of a time delay compensator according to an embodiment of the present invention, and FIG. 4 is a detailed configuration diagram illustrating a delay time compensator of a time delay compensator according to an embodiment of the present invention. to be.

Referring to Figure 3 to 4 will be described in detail the detailed components of the time delay compensation apparatus according to an embodiment of the present invention.

As shown in FIG. 3, the delay time measuring unit 100 of the time delay compensator 10 according to an embodiment of the present invention generates a pulse signal, converts it into an optical signal, and transmits the optical signal to the remote optical repeater 3. A measurement signal transmitter 110, a measurement signal receiver 120 for receiving a pulse response signal reflected from the remote optical repeater 3 and received as an optical signal as an analog signal and converting the signal into a digital signal, and the measurement signal transmitter The pulse signal converted into an optical signal by 110 is combined with a transmission signal input as an optical signal from the donor optical repeater 2 and transmitted to the remote optical repeater 3 or received from the remote optical repeater 3. Optical signal coupler 130 for separating an optical signal into a transmission signal transmitted to the donor optical repeater 2 and a pulse response signal input to the measurement signal receiver 120, and a pulse drive signal to the measurement signal transmitter 110. Remind to send And a measurement signal control calculator 140 for controlling the generation of the pulse signal of the positive signal transmitter 110 and calculating a delay time according to the transmission distance of the transmission signal using the digital signal received from the measurement signal receiver 120. do.

In more detail, the measurement signal transmitter 110 of the delay time measuring unit 100 receives a pulse driving signal from the measurement signal control calculator 140 and generates a pulse signal that generates an electrical pulse signal 111. ) And a laser diode unit 112 for converting the electrical pulse signal into an optical pulse signal in order to be combined with a transmission signal input from the donor optical repeater 2 as an optical signal, and the delay time measuring unit 100. Measurement signal receiving unit 120 of the) is a photodiode unit 121 for converting the pulse response signal received as an analog optical signal from the remote repeater 3 into an analog electric signal and an analog amplification to amplify the magnitude of the analog electric signal The unit 122 and an A / D converter unit 123 for converting the amplified analog electric signal into a digital signal.

Here, the pulse response signal received by the measurement signal receiver 120 of the delay time measurement unit 100 is reflected by the optical pulse signal of the measurement signal transmitter 110 from the remote optical repeater 3 which is an end point of the optical cable. The delay time measurement unit 100 of the time delay compensator 10 according to the exemplary embodiment of the present invention remotely generates the optical pulse signal by measuring the waveform of the pulse response signal reflected and returned. The delay time according to the transmission point and the end point of the optical cable in which the optical repeater 3 is located can be accurately measured.

Accordingly, the measurement signal control calculator 140 of the delay time measuring unit 100 sends a pulse driving signal to the measurement signal transmitting unit 110 and receives a pulse response signal as a digital signal from the measuring signal receiving unit 120. It is preferable that the program logic for counting the time to be formed of a field programmable gate array (FPGA) implemented in hardware.

In addition, the delay time measuring unit 100 isolates the pulse signal transmitted from the remote optical repeater 3 and the pulse response signal received from the remote optical repeater 3 to prevent signal interference 150 It is preferable to include).

On the other hand, as shown in Figure 4, the delay time compensation unit 200 of the time delay compensation device 10 according to an embodiment of the present invention, the donor optical repeater (2) is a transmission signal input from the base station (1) A transmission signal transmitter 210 having a path for transmitting to the base station, a transmission signal receiver 220 having a path for transmitting the transmission signal input from the donor optical repeater 2 to the base station 1, and the delay time. By performing the calculation process corresponding to the delay time according to the transmission distance of the transmission signal measured by the measuring unit 100 to obtain the transmission time of the transmission signal transmitted to the donor optical repeater 2 and the base station 1 and the transmission signal transmitter And a transmission time calculation control unit 230 for controlling the time delay of the transmission signal transmitted to the donor optical repeater 2 and the base station 1 by controlling the transmission signal receiver 220 and 210.

In more detail, the transmission signal transmitter 210 and the transmission signal receiver 220 of the delay time compensator 200 convert A / D converters 211 and 221 into digital signals, respectively. And delay units 212 and 222 delayed for a predetermined time under the control of the transfer time operation control unit 230, and converted into digital signals and passed through the delay units 212 and 222. D / A converters 213 and 223 for converting transmission signals into analog signals, and mixers 214 and 224 for converting frequencies of transmission signals transmitted to the base station 1 and the donor optical repeater 2 into specific frequencies. Include.

Here, the transmission signal transmitter 210 is a time delay operation for the transmission signal transmitted from the base station 1 of the LTE mobile communication system using the CDMA mobile communication network through the donor optical repeater 2 to the remote optical repeater 3 In this case, the analog signal received as the intermediate frequency signal of the 80 to 120 MHz band used in the base station from the base station 1 of the LTE mobile communication system passes through the A / D converter unit 211. The digital data signal is converted into a digital data signal, and the digital data signal is transmitted under the control of the transmission time calculation controller 230 for obtaining the transmission time of the transmission signal according to the delay time according to the transmission distance of the optical path while passing through the delay unit 212. The time is delayed, and the digital data signal whose transmission time is delayed is converted into an analog signal while passing through the D / A converter 213. The converted analog signal of the intermediate frequency state is converted into an analog RF signal of 800-900 MHz band through the mixer unit 214 in order to use the optical repeater system of the CDMA mobile communication network. (2) is coupled to the analog RF signal of the 800 ~ 900 MHz band is input to the donor optical repeater (2), the signal radiated from the remote optical repeater (3) to the terminal base station (1) of the LTE mobile communication system Synchronized with the signal emitted from the terminal.

In addition, the transmission signal receiver 220 is a time delay operation for the transmission signal transmitted from the remote optical repeater 3 to the base station 1 of the LTE mobile communication system using the CDMA mobile communication network via the donor optical repeater (2) In more detail, the analog signal received from the donor optical repeater 2 as the RF signal of the 800 to 900 MHz band used in the optical repeater system of the CDMA mobile communication network is used in the base station of the LTE mobile communication system. In order to be through the mixer unit 224, the frequency is converted into an analog signal of the 80 ~ 120 MHz band of the intermediate frequency signal, the analog signal of the intermediate frequency state of the frequency conversion is digital while passing through the A / D converter unit 221 The digital data signal is converted into a data signal, and the digital data signal passes through the delay unit 222 to obtain the transmission time of the transmission signal according to the delay time according to the transmission distance of the optical path. The transmission time is delayed under the control of the transmission time operation control unit 230, and the digital data signal whose transmission time is delayed is converted into an analog data signal while passing through the D / A converter unit 223, and the intermediate frequency state thus converted is The analog data signal is transmitted to the base station 1 of the LTE mobile communication system and the signal radiated from the base station 1 of the LTE mobile communication system to the terminal is synchronized with the signal radiated from the remote optical repeater (3) to the terminal.

like this, The signal radiated from the remote optical repeater 3 to the terminal through the transmission signal transmitter 210 and the signal radiated from the base station 1 of the LTE mobile communication system to the terminal through the transmission signal receiver 220 are The delayed time is radiated by the transmission time obtained by the transmission time operation control unit 230 of the delay time compensation unit 200. That is, the transmission time calculation control unit 230 of the delay time compensation unit 200 corresponds to the delay time according to the transmission distance and the signal radiated from the base station 1 of the LTE mobile communication system to the terminal and the remote optical repeater ( 3) to control the time delay of the signal passing through the transmission unit 210 and the delay unit 212, 222 of the transmission signal receiver 220 so that the signal radiated to the terminal can be synchronized.

Here, the tolerance range of the signal radiated from the base station 1 of the LTE mobile communication system to the terminal and the signal radiated from the remote optical repeater 3 to the terminal according to an embodiment of the present invention is a multipath of the LTE path. Considering this, it is within 4.69 which is the CP (Cyclic Prefix) insertion section of LTE system using Orthogoan Frequency Division Multiplexing (OFDM) symbol to prevent Inter-Symbol Interference (ISI) between two signals. desirable.

On the other hand, according to an embodiment of the present invention corresponding to the delay time according to the transmission distance measured by the delay time measuring unit 100 to time delay of the transmission signal transmitted to the base station 1 and the donor optical repeater (2) In order to control, the transmission time calculation controller 230 of the delay time compensator 200 performs a program logic for calculating the transmission time of the transmission signal, the transmission signal transmitter 210 and the transmission signal receiver 220. Program logic for generating and transmitting a control signal to control is preferably formed of a programmable semiconductor implemented in hardware.

As described above, the present invention has the effect of providing a time delay compensation device of the LTE mobile communication system that can reduce the system construction cost by using the optical repeater system of the CDMA mobile communication network.

In addition, the present invention has a delay time measuring unit for measuring the delay time according to the transmission distance of the donor optical repeater and the remote optical repeater using the optical signal reflected in the optical cable LTE mobile communication using a CDMA mobile communication network with improved reliability It is effective to provide a time delay compensation device of the system.

In addition, the present invention provides a LTE mobile communication using a CDMA mobile communication network in which a time delay compensation device having a programmable semiconductor having hardware implemented with a program logic for measuring a delay time according to a transmission distance, obtaining a transmission time, and controlling a time delay. It can be easily installed in the free space in the base station of the communication system to effectively implement the system installation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It is within the scope of the present invention that component changes to such an extent that they can be coped evenly within a range that does not deviate from the scope of the present invention.

1: base station 2: donor optical repeater
3: remote optical repeater 10: time delay compensation device
100: delay time measuring unit 110: measuring signal transmission unit
111: pulse signal generation unit 112: laser diode unit
120: measuring signal receiver 121: photodiode
122: analog amplifying unit 123, 211, 221: A / D converter unit
130: optical signal coupler 140: measurement signal control calculation unit
150: circulator 200: delay compensation unit
210: transmission signal transmitter 212,222: delay unit
213, 223: D / A converter section 214, 224: mixer section
230: transmission time operation control unit

Claims (9)

CDMA for compensating the time delay of a transmission signal generated between the donor optical repeater and the remote optical repeater of an LTE mobile communication system using a CDMA mobile communication network including a donor optical repeater and a remote optical repeater for using an optical path as a transmission medium. In the time delay compensation device of the LTE mobile communication system using a mobile communication network,
Generates a pulse signal and combines the pulse signal with a transmission signal input from the donor optical repeater to an optical signal and transmits the pulse response signal reflected from the remote optical repeater to the pulse signal as an optical signal. Delay time measuring unit for receiving and measuring the delay time according to the transmission distance of the transmission signal; And
And a delay time compensator for controlling a time delay of a transmission signal transmitted to the base station and the donor optical repeater in response to the delay time according to the transmission distance measured by the delay time measurement unit.
The delay time compensation unit,
A transmission signal transmitter configured to form a path for transmitting the transmission signal input from the base station to the donor optical repeater;
A transmission signal receiver configured to form a path for transmitting a transmission signal input from a donor optical repeater to a base station; And
The transmission time of the transmission signal transmitted to the donor optical repeater and the base station is calculated by performing a calculation process corresponding to the delay time according to the transmission distance of the transmission signal measured by the delay time measuring unit. And a transmission time calculation control unit controlling the time delay of the transmission signal transmitted to the donor optical repeater and the base station. 2. The time delay compensation apparatus of the LTE mobile communication system using a CDMA mobile communication network.
The method of claim 1, wherein the delay time measuring unit,
A measurement signal transmitter for generating a pulse signal and converting the optical signal into a remote repeater;
A measurement signal receiver which receives a pulse response signal reflected from the remote repeater and received as an optical signal as an analog signal and converts the signal into a digital signal;
The pulse signal converted into an optical signal by the measuring signal transmitter is combined with a transmission signal input as an optical signal from the donor optical repeater and transmitted to a remote optical repeater, or an optical signal received from the remote optical repeater is transmitted to a donor optical repeater. An optical signal coupler that separates the transmission signal into a pulse response signal input to the measurement signal receiver;
A measurement signal control calculator for controlling pulse generation of the measurement signal transmitter by sending a pulse driving signal to the measurement signal transmitter and calculating a delay time according to a transmission distance of the transmission signal using a digital signal received from the measurement signal receiver; Time delay compensation device of the LTE mobile communication system using a CDMA mobile communication network comprising a.
The method of claim 2, wherein the measurement signal control calculation unit,
A CDMA mobile communication network comprising a programmable semiconductor having a hardware implemented therein, the program logic for transmitting a pulse driving signal to the measurement signal transmitter and counting a time from the measurement signal receiver to a pulse response signal as a digital signal. Time delay compensation device of the LTE mobile communication system used.
The method of claim 2, wherein the delay time measuring unit,
And a circulator for isolating the pulse signal transmitted to the remote optical repeater and the pulse response signal received from the remote optical repeater.
The measurement signal transmission unit according to any one of claims 2 to 4, wherein the delay time measurement unit
An optical pulse signal for combining a pulse signal generator for receiving an electric pulse signal from the measurement signal control calculator and generating an electrical pulse signal and a transmission signal input as an optical signal from the donor optical repeater. Time delay compensation device of the LTE mobile communication system using a CDMA mobile communication network comprising a laser diode unit for converting.
The measurement signal receiver of any one of claims 2 to 4, wherein
A photodiode for converting a pulse response signal received as an analog optical signal from the remote repeater into an analog electrical signal, an analog amplifying unit for amplifying the magnitude of the analog electrical signal and A for converting the amplified analog electrical signal into a digital signal. Time delay compensation device of the LTE mobile communication system using a CDMA mobile communication network comprising a / D converter.
delete The method of claim 1, wherein the transmission time calculation control unit,
It is characterized in that the program logic for calculating the transmission time of the transmission signal and the program logic for generating and transmitting the control signal for controlling the transmission signal transmitter and the transmission signal receiver is formed of a programmable semiconductor implemented in hardware Time delay compensation device of LTE mobile communication system using CDMA mobile communication network.
The method according to claim 1, wherein the transmission signal transmitter and the transmission signal receiver,
An A / D converter unit for converting a transmission signal input as an analog signal into a digital signal, a delay unit for delaying the transmission signal converted into the digital signal for a predetermined time under the control of the transmission time operation control unit, and a digital signal And a mixer for converting a transmission signal passing through the delay unit into an analog signal and converting a frequency of a transmission signal transmitted to the base station and the donor optical repeater to a specific frequency. Time delay compensation device of LTE mobile communication system using CDMA mobile communication network.

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